Innovative Energy & Research
Open Access

Research Article

Analysis: Magnetic Resonance Targets Telomeres/Telomerase for Cancer Treatment?

Jacobson JI^*

Institute of Theoretical Physics and Advanced Studies for Biophysical Research, Jupiter, Florida, USA

*Corresponding Author:

Jacobson JI
Institute of Theoretical Physics and Advanced Studies for Biophysical Research
Jupiter, Florida, USA
Tel: +5617468719
E-mail: drjijacobson@yahoo.com

Received date: March 11, 2016; Accepted date: May 16, 2016; Published date: May 23, 2016

Citation: Jacobson JI (2016) Analysis: Magnetic Resonance Targets Telomeres/Telomerase for Cancer Treatment? Innov Ener Res 5:135. doi:10.4172/ier.1000135

Copyright: © 2016 Jacobson JI. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

This paper essentially poses the question, “Is it possible to calculate target-specific magnetic resonance energies to restore bio molecular order and inhibit telomerase production under conditions of increasing entropy, even as cells pass M2 checkpoints?” Indeed, a diversity of positive experimental outcomes has pointed to the possibility that non-ionizing radiation (NIR’s) produce positive bio effects of predictable nature. The hypothetical construct is that Pico-Tesla range magnetic fields are physiologic and may possibly affect molecules and molecular assemblies through the piezoelectric effect; most especially due to the supposed quasi-crystalline semi conductive nature of various biological structures. The initial physical mechanism is hypothesized to be photon-phonon transductions, i.e., electro mechanical conversions, via resonance phenomena. Utilizing a novel particle-wave equation, mc²=BvLq, specified magnetic flux densities have been calculated, formulating a possible system of dual resonance. The energy produced by the interaction of the organism and the magnetic field is set equal to the intrinsic energy of a molecule. The outcome of this methodology may possibly provide a new, noninvasive holistic paradigm for adjuvant treatment of cancer. In support of said hypothesis, various experimental outcomes are considered, wherein the given method was utilized to establish magnetic resonance protocols, based on molecular species known to be associated with pathophysiologic conditions including cancer. Thus, if successful, then a possible new adjunctive, non-invasive and non-significant risk approach for telomerase inhibition with conventional cancer therapy is proposed.

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